local M = {} local Arc = require 'Arc' local CompoundDial = require 'CompoundDial' local CriticalText = require 'CriticalText' local Text = require 'Text' local Line = require 'Line' local LabelPlot = require 'LabelPlot' local Table = require 'Table' local Util = require 'Util' local __string_format = string.format local CORETEMP_PATH = '/sys/devices/platform/coretemp.0/hwmon/hwmon%i/%s' local NUM_PHYSICAL_CORES = 4 local NUM_THREADS_PER_CORE = 2 local NUM_ROWS = 5 local TABLE_CONKY = {} for r = 1, NUM_ROWS do TABLE_CONKY[r] = {} TABLE_CONKY[r].pid = '${top pid '..r..'}' TABLE_CONKY[r].cpu = '${top cpu '..r..'}' end local _MODULE_Y_ = 614 local _DIAL_INNER_RADIUS_ = 30 local _DIAL_OUTER_RADIUS_ = 42 local _DIAL_SPACING_ = 1 local _SEPARATOR_SPACING_ = 20 local _TEXT_SPACING_ = 22 local _PLOT_SECTION_BREAK_ = 23 local _PLOT_HEIGHT_ = 56 local _TABLE_SECTION_BREAK_ = 20 local _TABLE_HEIGHT_ = 114 local _create_core_ = function(cores, id, x, y) local conky_loads = {} local conky_freqs = {} for c = 0, NUM_PHYSICAL_CORES * NUM_THREADS_PER_CORE - 1 do if Util.read_file('/sys/devices/system/cpu/cpu'..c..'/topology/core_id', nil, '*n') == id then table.insert(conky_loads, '${cpu cpu'..(c+1)..'}') table.insert(conky_freqs, '${freq '..c..'}') end end local hwmon_index = -1 while Util.read_file(string.format(CORETEMP_PATH, hwmon_index, 'name'), nil, '*l') ~= 'coretemp' do hwmon_index = hwmon_index + 1 end cores[id +1] = { dials = _G_Widget_.CompoundDial{ x = x, y = y, inner_radius = _DIAL_INNER_RADIUS_, outer_radius = _DIAL_OUTER_RADIUS_, spacing = _DIAL_SPACING_, num_dials = NUM_THREADS_PER_CORE, critical_limit = '>0.8' }, inner_ring = _G_Widget_.Arc{ x = x, y = y, radius = _DIAL_INNER_RADIUS_ - 2, theta0 = 0, theta1 = 360 }, coretemp_text = _G_Widget_.CriticalText{ x = x, y = y, x_align = 'center', y_align = 'center', append_end = '°C', critical_limit = '>90' }, coretemp_path = string.format(CORETEMP_PATH, hwmon_index, 'temp'..(id + 2)..'_input'), conky_loads = conky_loads, conky_freqs = conky_freqs } end local header = _G_Widget_.Header{ x = _G_INIT_DATA_.LEFT_X, y = _MODULE_Y_, width = _G_INIT_DATA_.SECTION_WIDTH, header = 'PROCESSOR' } --we assume that this cpu has 4 physical cores with 2 logical each local cores = {} for c = 0, NUM_PHYSICAL_CORES - 1 do local dial_x = _G_INIT_DATA_.LEFT_X + _DIAL_OUTER_RADIUS_ + (_G_INIT_DATA_.SECTION_WIDTH - 2 * _DIAL_OUTER_RADIUS_) * c / 3 local dial_y = header.bottom_y + _DIAL_OUTER_RADIUS_ _create_core_(cores, c, dial_x, dial_y) end local _RIGHT_X_ = _G_INIT_DATA_.LEFT_X + _G_INIT_DATA_.SECTION_WIDTH local _PROCESS_Y_ = header.bottom_y + _DIAL_OUTER_RADIUS_ * 2 + _PLOT_SECTION_BREAK_ local process = { label = _G_Widget_.Text{ x = _G_INIT_DATA_.LEFT_X, y = _PROCESS_Y_, text = 'R | S | D | T | Z' }, value = _G_Widget_.Text{ x = _RIGHT_X_, y = _PROCESS_Y_, x_align = 'right', text_color = _G_Patterns_.BLUE, text = ' | | | | ' } } local _FREQ_Y_ = _PROCESS_Y_ + _TEXT_SPACING_ local ave_freq = { label = _G_Widget_.Text{ x = _G_INIT_DATA_.LEFT_X, y = _FREQ_Y_, text = 'Ave Freq' }, value = _G_Widget_.Text{ x = _RIGHT_X_, y = _FREQ_Y_, x_align = 'right', text_color = _G_Patterns_.BLUE, text = '' } } local _SEP_Y_ = _FREQ_Y_ + _SEPARATOR_SPACING_ local separator = _G_Widget_.Line{ p1 = {x = _G_INIT_DATA_.LEFT_X, y = _SEP_Y_}, p2 = {x = _RIGHT_X_, y = _SEP_Y_} } local _LOAD_Y_ = _SEP_Y_ + _SEPARATOR_SPACING_ local total_load = { label = _G_Widget_.Text{ x = _G_INIT_DATA_.LEFT_X, y = _LOAD_Y_, text = 'Total Load' }, value = _G_Widget_.CriticalText{ x = _RIGHT_X_, y = _LOAD_Y_, x_align = 'right', append_end = '%', critical_limit = '>80' } } local _PLOT_Y_ = _LOAD_Y_ + _PLOT_SECTION_BREAK_ local plot = _G_Widget_.LabelPlot{ x = _G_INIT_DATA_.LEFT_X, y = _PLOT_Y_, width = _G_INIT_DATA_.SECTION_WIDTH, height = _PLOT_HEIGHT_ } local tbl = _G_Widget_.Table{ x = _G_INIT_DATA_.LEFT_X, y = _PLOT_Y_ + _PLOT_HEIGHT_ + _TABLE_SECTION_BREAK_, width = _G_INIT_DATA_.SECTION_WIDTH, height = _TABLE_HEIGHT_, num_rows = NUM_ROWS, 'Name', 'PID', 'CPU (%)' } local update = function(cr) local conky = Util.conky local char_count = Util.char_count local load_sum = 0 local freq_sum = 0 for c = 1, NUM_PHYSICAL_CORES do local core = cores[c] local conky_loads = core.conky_loads local conky_freqs = core.conky_freqs for t = 1, NUM_THREADS_PER_CORE do local percent = Util.conky_numeric(conky_loads[t]) * 0.01 CompoundDial.set(core.dials, t, percent) load_sum = load_sum + percent freq_sum = freq_sum + Util.conky_numeric(conky_freqs[t]) end CriticalText.set(core.coretemp_text, cr, Util.round_to_string(0.001 * Util.read_file(core.coretemp_path, nil, '*n'))) end local process_glob = Util.execute_cmd('ps -A -o s h') -- subtract one from running b/c ps will always be "running" Text.set(process.value, cr, __string_format('%s | %s | %s | %s | %s', (char_count(process_glob, 'R') - 1), char_count(process_glob, 'S'), char_count(process_glob, 'D'), char_count(process_glob, 'T'), char_count(process_glob, 'Z'))) Text.set(ave_freq.value, cr, Util.round_to_string(freq_sum / NUM_PHYSICAL_CORES / NUM_THREADS_PER_CORE) .. ' MHz') local load_percent = Util.round(load_sum / NUM_PHYSICAL_CORES / NUM_THREADS_PER_CORE, 2) CriticalText.set(total_load.value, cr, Util.round_to_string(load_percent * 100)) LabelPlot.update(plot, load_percent) for r = 1, NUM_ROWS do local pid = conky(TABLE_CONKY[r].pid, '(%S+)') if pid ~= '' then local cpu = conky(TABLE_CONKY[r].cpu) local comm = Util.read_file('/proc/'..pid..'/stat', '%d+%s+%((.+)%)') Table.set(tbl, cr, 1, r, comm) Table.set(tbl, cr, 2, r, pid) Table.set(tbl, cr, 3, r, cpu) end end end _MODULE_Y_ = nil _DIAL_INNER_RADIUS_ = nil _DIAL_OUTER_RADIUS_ = nil _DIAL_SPACING_ = nil _TEXT_Y_OFFSET_ = nil _SEPARATOR_SPACING_ = nil _TEXT_SPACING_ = nil _PLOT_SECTION_BREAK_ = nil _PLOT_HEIGHT_ = nil _TABLE_SECTION_BREAK_ = nil _TABLE_HEIGHT_ = nil _create_core_ = nil _FREQ_Y_ = nil _LOAD_Y_ = nil _RIGHT_X_ = nil _SEP_Y_ = nil _PROCESS_Y_ = nil _PLOT_Y_ = nil local draw_static = function(cr) Text.draw(header.text, cr) Line.draw(header.underline, cr) for c = 1, NUM_PHYSICAL_CORES do local this_core = cores[c] Arc.draw(this_core.inner_ring, cr) CompoundDial.draw_static(this_core.dials, cr) end Text.draw(process.label, cr) Text.draw(ave_freq.label, cr) Line.draw(separator, cr) Text.draw(total_load.label, cr) LabelPlot.draw_static(plot, cr) Table.draw_static(tbl, cr) end local draw_dynamic = function(cr) update(cr) for c = 1, NUM_PHYSICAL_CORES do local this_core = cores[c] CompoundDial.draw_dynamic(this_core.dials, cr) CriticalText.draw(this_core.coretemp_text, cr) end Text.draw(process.value, cr) Text.draw(ave_freq.value, cr) CriticalText.draw(total_load.value, cr) LabelPlot.draw_dynamic(plot, cr) Table.draw_dynamic(tbl, cr) end M.draw_static = draw_static M.draw_dynamic = draw_dynamic return M